CN112821827B - Disturbance suppression system for harmonic reducer of CMG frame system - Google Patents
Disturbance suppression system for harmonic reducer of CMG frame system Download PDFInfo
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- CN112821827B CN112821827B CN202110037444.2A CN202110037444A CN112821827B CN 112821827 B CN112821827 B CN 112821827B CN 202110037444 A CN202110037444 A CN 202110037444A CN 112821827 B CN112821827 B CN 112821827B
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
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- H02P21/0007—Control strategies in general, e.g. linear type, e.g. P, PI, PID, using robust control using sliding mode control
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02P—CONTROL OR REGULATION OF ELECTRIC MOTORS, ELECTRIC GENERATORS OR DYNAMO-ELECTRIC CONVERTERS; CONTROLLING TRANSFORMERS, REACTORS OR CHOKE COILS
- H02P21/00—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation
- H02P21/05—Arrangements or methods for the control of electric machines by vector control, e.g. by control of field orientation specially adapted for damping motor oscillations, e.g. for reducing hunting
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Abstract
The invention relates to a disturbance suppression system for a harmonic reducer of a CMG frame system, which can effectively suppress harmonic installation error disturbance and low-frequency mechanical resonance. According to the invention, a double-rotation variable angle measurement control strategy is adopted to inhibit the mounting error disturbance of the harmonic reducer, a double-ring nonsingular sliding mode variable structure control strategy is adopted to inhibit the low-frequency mechanical resonance frequency of the motor, the problems of harmonic mounting error disturbance and low-frequency mechanical resonance are effectively inhibited, and the control performance of an indirect drive structure is improved.
Description
Technical Field
The invention relates to a disturbance suppression system for a harmonic reducer of a CMG frame system, which can effectively suppress harmonic installation error disturbance and low-frequency mechanical resonance.
Background
The direct drive structure adopts a permanent magnet synchronous motor to directly drive, has the advantages of high control precision and the defects that a frame motor needs to directly bear coupling torque, has large power consumption and heavy weight and is generally used for medium and small CMG; the brushless direct current motor with the indirect drive structure and the reducer for transmission have the advantages that coupling torque is reduced through a speed reduction link, motor output torque and drive power consumption can be reduced, and the control precision is low. When the control moment gyro is required to realize high-precision control, large-moment output and low power consumption, the traditional single direct-drive structure and indirect drive are difficult to meet the requirement of the high-precision control moment gyro, and a novel frame drive assembly form is required to be adopted.
In order to improve the control performance of the indirect drive structure, the structure form of a permanent magnet synchronous motor, an angle measuring sensor, a harmonic reducer and an angle measuring sensor is adopted. The permanent magnet synchronous motor is adopted to reduce the output torque fluctuation of the motor, and angle measuring sensors are arranged in front of and behind the harmonic reducer.
The harmonic reducer has the advantages of large transmission ratio, high precision, small volume, light weight and the like, but has the defects of flexibility, nonlinear friction, low damping and the like due to the structural characteristics, and two types of interference frequencies mainly exist in a system by analyzing the frequency of the angular speed of the output shaft of the CMG frame.
One type of disturbance is harmonic installation error disturbances. The method is embodied in 2,4,6,8 frequency multiplication of the motor side angular speed of an input shaft of a harmonic reducer, mainly caused by motion errors, namely errors of a rigid gear pair and a flexible gear pair, and errors of a wave generator.
The other type is low-frequency mechanical resonance frequency, especially the torsional rigidity of the harmonic reducer is smaller under the condition that the load moment is smaller, the resonance frequency is correspondingly smaller, and the nonlinear hysteresis characteristic of the torsional rigidity of the harmonic reducer causes the nonlinear change of the resonance frequency. Mechanical resonance frequency f of frame system n And moment of inertia and torsional stiffness K l There is a relationship that,
for the mechanical resonance frequency of low frequency, there are some documents that use an H ∞ controller and an extended state observer to suppress the resonance frequency in the control moment gyro frame, but this method is not conducive to digital implementation
Disclosure of Invention
The technical problem solved by the invention is as follows: the disturbance suppression system for the harmonic reducer of the CMG frame system is used for overcoming the defects in the prior art, effectively suppressing the problems of harmonic installation error disturbance and low-frequency mechanical resonance and improving the control performance of an indirect drive structure.
The technical solution of the invention is as follows: the utility model provides a CMG frame system harmonic speed reducer ware disturbance suppression system which characterized in that: and a double-rotation variable angle measurement control strategy is adopted to inhibit the mounting error disturbance of the harmonic reducer, and a double-ring nonsingular sliding mode variable structure control strategy is adopted to inhibit the low-frequency mechanical resonance frequency of the motor.
Further, the device comprises an outer side rotation transformation controller, a motor side controller, a PWM generator, an inverter, a motor frame, a coordinate transformation module and a position demodulation module.
Further, the outer side rotation controller receives a difference value between the frame angle set value and the frame outer side angle value, and outputs a motor side angular velocity reference value to the motor side controller after control.
Further, the outer rotary transformer controller comprises a position ring controller and a speed ring controller; the position ring controller realizes position ring control by using a PD control method according to a difference value between a frame angle set value and a frame outside angle value, and outputs a frame outside angular velocity reference value to the speed ring controller, and the speed ring controller realizes angular velocity control by using a P control method according to the frame outside angular velocity reference value and the frame outside angular velocity value, and outputs a motor side angular velocity reference value to the motor side controller.
Further, the motor side controller receives a motor side angular velocity reference value, an exciting current reference value, a motor angular velocity measurement feedback value, a motor side angular value, an exciting current feedback value and a torque current feedback value, performs sliding mode control, and outputs an exciting voltage signal and a torque voltage signal, and the exciting voltage signal and the torque voltage signal sequentially pass through the PWM generator and the inverter to drive the motor frame to rotate; the excitation voltage signal and the moment voltage signal are respectively a d-axis stator voltage component and a q-axis stator voltage component.
Further, the coordinate transformation module collects three-phase current signals of the motor frame, and outputs an excitation current feedback value and a torque current feedback value to the motor side controller after coordinate transformation.
Further, the position demodulation module acquires a frame outer side rotary transformer signal and a motor side rotary transformer signal, and outputs the motor side angle value, the motor side angular velocity value, the frame outer side angle value and the frame outer side angular velocity value to the motor side controller and the outer side rotary transformer controller respectively after demodulation.
Further, the dual-rotation angle measurement control strategy is that a rotary transformer is respectively arranged inside and outside the speed reducer, the inner rotary transformer is used for detecting the angular position of the motor, the outer rotary transformer is used for detecting the angular position output by the frame, and a frame outer rotary transformer signal and a motor side rotary transformer signal are respectively generated.
Further, the motor side controller comprises an outer ring controller and an inner ring current controller;
the control law of the outer ring controller is as follows:
Wherein:for the virtual control quantity corresponding to the excitation current reference signal, ω Inner part Is the mechanical angular velocity, x, of the motor side 1 、x 2 For a defined sliding-mode state variable, in the absence of a trigger signal>For a reference value of the angular speed of the motor side, is determined>The mechanical angular acceleration at the motor side, the moment of inertia of the load at the motor side, D, k, and delta 0 For controlling the constant of the parameter, sign (-) is a sign function, λ>0 is a design parameter, q, p are positive odd numbers, and q is<p<2q。
Further, the control law of the inner loop current controller is as follows:
wherein u is d 、u q Is a d-axis, q-axis stator voltage component, i d 、i q Are d-axis and q-axis stator current components,calculating the error for the current i d * 、i q * D-axis and q-axis stator current reference values; r is stator resistance, L is motor inductance, L d 、L q Is a direct-axis and quadrature-axis synchronous inductor of the motor, omega e For electrical angular velocity, psi, of the motor rm For rotor flux linkage, gamma 1 >0,δ 1 >0,γ 2 >0,δ 2 >0, are all constants.
Compared with the prior art, the invention has the advantages that:
(1) The invention provides a frame control method, which adopts a double-rotation angle measurement scheme to inhibit 2,4,6 and 8 rotation frequencies of a harmonic reducer and improve the control precision of a frame system.
(2) The invention provides a control method of a motor, which utilizes a control strategy of a rotational position ring and a speed ring on the outer side of a frame and a motor side rotational dual-ring nonsingular sliding mode to inhibit the mechanical resonant frequency of a system and improve the control precision of the frame system.
Drawings
FIG. 1 is a general block diagram of a harmonic reducer interference suppression system of a CMG frame system;
FIG. 2 is a schematic diagram of a double-loop nonsingular terminal sliding film control strategy;
fig. 3, 4, and 5 are amplitude/frequency graphs of the control modes (1) (2) (3) in the embodiments, respectively.
Detailed Description
In order to better understand the technical solutions, the technical solutions of the present application are described in detail below with reference to the drawings and specific embodiments, and it should be understood that the specific features in the embodiments and examples of the present application are detailed descriptions of the technical solutions of the present application, and are not limitations of the technical solutions of the present application, and the technical features in the embodiments and examples of the present application may be combined with each other without conflict.
The disturbance suppression system for the CMG frame system harmonic reducer provided by the embodiment of the present application is further described in detail with reference to the drawings in the specification, and specific implementations may include (as shown in fig. 1): the angular position ring and the angular velocity ring are realized by utilizing the angular information of the angular measurement rotary transformer on the outer side of the frame, and the double-ring nonsingular sliding mode velocity ring controller is realized by utilizing the angular information of the angular measurement rotary transformer on the side of the motor. Realizing position loop control and speed loop control by utilizing the frame outside rotation angle value/angular velocity value and a frame given angular velocity reference value, wherein the position loop adopts a proportional differential control mode (PD mode), and the speed loop adopts a proportional control mode (P mode); and setting a double-ring nonsingular sliding mode speed loop controller by utilizing the information of the rotation angle at the inner side of the motor, wherein the output of the rotation speed loop controller at the outer side is used as the input of the rotation speed loop controller at the side of the motor, and the output of the nonsingular sliding mode controller is the reference value of the voltage component of the dq shaft stator of the motor.
The scheme provided by the embodiment of the application comprises an outer-side rotation transformation controller, a motor-side controller, a PWM generator, an inverter, a motor frame, a coordinate transformation module and a position demodulation module. And the outer side rotary transformer controller receives the difference value between the frame angle set value and the frame outer side angle value, and outputs a motor side angular speed reference value to the motor side controller after controlling. The outer side rotary transformer controller comprises a position ring controller and a speed ring controller; the position ring controller realizes position ring control by using a PD control method according to a difference value between a frame angle set value and a frame outside angle value, and outputs a frame outside angular velocity reference value to the speed ring controller, and the speed ring controller realizes angular velocity control by using a P control method according to the frame outside angular velocity reference value and the frame outside angular velocity value, and outputs a motor side angular velocity reference value to the motor side controller. The motor side controller receives a motor side angular speed reference value, an excitation current reference value, a motor angular speed measurement feedback value, a motor side angle value, an excitation current feedback value and a torque current feedback value, performs sliding mode control and then outputs an excitation voltage signal and a torque voltage signal, and the excitation voltage signal and the torque voltage signal sequentially pass through the PWM generator and the inverter to drive the motor frame to rotate; the excitation voltage signal and the moment voltage signal are respectively a d-axis stator voltage component and a q-axis stator voltage component.
Further, the coordinate transformation module collects three-phase current signals of the motor frame, and outputs an exciting current feedback value and a torque current feedback value to the motor side controller after coordinate transformation.
Further, the position demodulation module acquires a frame outer side rotary transformer signal and a motor side rotary transformer signal, and outputs the motor side angle value, the motor side angular velocity value, the frame outer side angle value and the frame outer side angular velocity value to the motor side controller and the outer side rotary transformer controller respectively after demodulation.
Further, the dual-rotation angle measurement control strategy is that a rotary transformer is respectively arranged inside and outside the speed reducer, the inner rotary transformer is used for detecting the angular position of the motor, the outer rotary transformer is used for detecting the angular position output by the frame, and a frame outer rotary transformer signal and a motor side rotary transformer signal are respectively generated.
The double-rotation structure is a structural form for suppressing harmonic installation error disturbance, and the motor side angle measurement rotary transformer and the frame shaft outer side angle measurement rotary transformer participate in closed-loop control at the same time. The motor side rotation transformer corresponds to the mechanical position of the permanent magnet synchronous motor and is named as the motor side rotation transformer, and the rotation transformer is demodulated into 16-bit coarse pole demodulation data which are used for motor phase change and position angle/angular speed input of a motor side controller; the mechanical position of the output end rotary transformer corresponding to the frame output shaft is named as the frame outer side rotary transformer, and the rotary transformer is demodulated into 21-bit coarse-fine coupling data which are used for inputting the position angle and the angular speed of the frame side controller.
Further, the double-ring nonsingular sliding mode variable structure controller refers to a control strategy for suppressing the low-frequency mechanical resonant frequency of the system, and the double-ring nonsingular terminal sliding mode control strategy in the motor side controller comprises an outer ring controller and an inner ring current controller.
Further, as shown in fig. 2, in one possible implementation, the double-loop nonsingular sliding mode variable structure controller includes an outer loop controller and an inner loop current controller.
Further, in one possible implementation, the outer-loop controller is:
Wherein: λ >0 is a design parameter, q, p are positive odd numbers, and q < p <2q.
The outer-ring controller is designed in such a way that,
wherein:corresponding to the excitation current reference signal, omega, for the virtual control quantity Inner part Is the mechanical angular velocity, x, of the motor side 1 、x 2 For a defined sliding-mode state variable, ->For a reference value of the angular speed of the motor side, is determined>The mechanical angular acceleration at the motor side, the moment of inertia of the load at the motor side, D, k, and delta 0 For controlling the constant of the parameter, sign (-) is a sign function, λ>0 is a design parameter, q and p are positive odd numbers, and q is<p<2q。
Further, in one possible implementation, the inner loop current controller:
the current errors are respectively:
the inner-loop current controller is designed such that,
wherein u is d 、u q Is a d-axis, q-axis stator voltage component, i d 、i q Are d-axis and q-axis stator current components,calculating the error for the current i d * 、i q * D-axis and q-axis stator current reference values; r is stator resistance, L is motor inductance, L d 、L q Is a direct-axis and quadrature-axis synchronous inductor of the motor, omega e For electrical angular velocity, psi, of the motor rm For rotor flux linkage, gamma 1 >0,δ 1 >0,γ 2 >0,δ 2 >0, are all constants.
The working principle of the invention is as follows: the harmonic frequency doubling inhibition is solved by adopting a double-rotation angle measurement mode, and the proved effect is obvious. Harmonic reducer drive error can be expressed as a function of input angular position:
in the formula [ theta ] m For the input angular position of the wave generator, A i (i =1,2,3 \8230;) is the magnitude of the drive error at each frequency,the initial phase of the transmission error at each frequency.
Examples
The process of the present invention will be described in detail with reference to examples.
The control schemes of a control moment gyro product in an indirect drive mode are as follows, wherein the scheme 3 is the patent mode.
As shown in fig. 3, control method (1): the unit sensor + traditional PID controller mode:
the angular position ring and the angular velocity ring are realized by using only the angular information of the angular resolver outside the frame. The frame outer side rotation angle value/angular velocity value and the frame given angular velocity reference value realize position loop control and velocity loop control, the position loop adopts a proportional differential control mode (PD mode), the velocity loop adopts a proportional control mode (P mode), and the output is a motor q-axis current reference value; the inner side of the motor is provided with a current controller, the input of the current controller is a dq axis current reference value and a feedback value, proportional-integral control (PI mode) is adopted, and the output of the controller is a dq axis stator voltage component reference value of the motor. The lower graph is a frequency spectrum analysis curve when the angular velocity is 1 °/s under the control mode, wherein the stability of the angular velocity is 0.171 °/s, the frequency mainly influencing the stability is the frequency multiplication of the angular velocity on the motor side, and the maximum 6 frequency multiplication component is 0.0582.
As shown in fig. 4, control method (2): dual position sensor + traditional PID controller mode:
and simultaneously using the angle information of the angle measuring rotary transformer outside the frame and the angle information of the angle measuring rotary transformer at the motor side. The angular position ring and the angular velocity ring are realized by utilizing the angular information of the angular measurement rotary transformer outside the frame, and the velocity ring current ring controller is realized by utilizing the angular information of the angular measurement rotary transformer outside the motor. Realizing position loop control and speed loop control by utilizing the frame outside rotation angle value/angular velocity value and a frame given angular velocity reference value, wherein the position loop adopts a proportional differential control mode (PD mode), and the speed loop adopts a proportional control mode (P mode); the method comprises the steps that a speed ring controller is set by utilizing the information of the rotation angle at the inner side of the motor, the output of the rotation speed ring controller at the outer side is used as the input of the rotation speed ring controller at the motor side, the speed ring adopts proportional integral control (PI mode), the output of the rotation speed ring controller at the motor side is used as the reference value input of a current ring controller, the current ring controller adopts proportional integral control (PI mode), and the output of the controller is used as the reference value of the stator voltage component of the dq axis of the motor. The lower graph is a frequency spectrum analysis curve when the angular velocity is 1 degree/s under the control mode, wherein the stability of the angular velocity is 0.0616 degrees/s, after the double sensors are adopted, the main frequency influencing the stability is changed into mechanical resonance frequency, about 20Hz, the frequency multiplication components of 2,4,6 and 8 of the angular velocity of the motor side are greatly reduced, and the frequency multiplication component of 6 is reduced to 0.0178.
As shown in fig. 5, control mode (3): this patent control mode adopts, and the nonsingular sliding mode of two position sensor + dicyclo becomes the structural control mode:
the lower graph is a frequency spectrum analysis curve when the angular velocity is 1 degree/s under the control mode, wherein the stability of the angular velocity is 0.0461 degree/s, after the control mode of the patent is adopted, the mechanical resonance frequency influencing the stability and the frequency doubling component of the angular velocity are both greatly reduced, wherein the frequency doubling component of the angular velocity 6 on the motor side is reduced to 0.00083, and the mechanical resonance frequency is also greatly reduced.
Comparing three control modes, after interference suppression, the stability of angular velocity is far better than that of scheme 2 and scheme 1 in scheme 3 provided by the patent.
It will be apparent to those skilled in the art that various changes and modifications may be made in the present application without departing from the spirit and scope of the application. Thus, if such modifications and variations of the present application fall within the scope of the claims of the present application and their equivalents, the present application is intended to include such modifications and variations as well.
Those skilled in the art will appreciate that those matters not described in detail in the present specification are well known in the art.
Claims (6)
1. The utility model provides a CMG frame system harmonic speed reducer ware disturbance suppression system which characterized in that: a double-rotation-transformer angle measurement control strategy is adopted to restrain the mounting error disturbance of the harmonic reducer, and a double-ring nonsingular sliding mode structure control strategy is adopted to restrain the low-frequency mechanical resonance frequency of the motor;
the device comprises an outer side rotary transformer controller, a motor side controller, a PWM generator, an inverter, a motor frame, a coordinate transformation module and a position demodulation module;
the outer side rotation transformer controller receives a difference value between a frame angle set value and a frame outer side angle value, and outputs a motor side angular speed reference value to the motor side controller after control;
the outer side rotary transformer controller comprises a position ring controller and a speed ring controller; the position ring controller realizes position ring control by using a PD control method according to a difference value between a frame angle set value and a frame outside angle value, and outputs a frame outside angular velocity reference value to the speed ring controller, the speed ring controller realizes angular velocity control by using a P control method according to the frame outside angular velocity reference value and the frame outside angular velocity value, and outputs a motor side angular velocity reference value to the motor side controller;
the double-rotation angle measurement control strategy is characterized in that a rotary transformer is respectively arranged inside and outside the speed reducer, the inner rotary transformer is used for detecting the angular position of the motor, the outer rotary transformer is used for detecting the angular position output by the frame, and a frame outer rotary transformer signal and a motor side rotary transformer signal are respectively generated.
2. The CMG frame system harmonic reducer disturbance rejection system of claim 1, wherein: the motor side controller receives a motor side angular speed reference value, an exciting current reference value, a motor angular speed measuring feedback value, a motor side angular value, an exciting current feedback value and a torque current feedback value, performs sliding mode control and then outputs an exciting voltage signal and a torque voltage signal, and the exciting voltage signal and the torque voltage signal sequentially pass through the PWM generator and the inverter to drive the motor frame to rotate; the excitation voltage signal and the moment voltage signal are respectively a d-axis stator voltage component and a q-axis stator voltage component.
3. The CMG framework system harmonic reducer disturbance suppression system of claim 1, wherein: the coordinate transformation module collects three-phase current signals of the motor frame, and outputs an exciting current feedback value and a torque current feedback value to the motor side controller after coordinate transformation.
4. The CMG framework system harmonic reducer disturbance suppression system of claim 1, wherein: the position demodulation module acquires a frame outer side rotary transformer signal and a motor side rotary transformer signal, and outputs the motor side angle value, the motor side angular velocity value, the frame outer side angle value and the frame outer side angular velocity value to the motor side controller and the outer side rotary transformer controller respectively after demodulation.
5. The CMG frame system harmonic reducer disturbance rejection system of claim 4, wherein: the motor side controller comprises an outer ring controller and an inner ring current controller;
the control law of the outer ring controller is as follows:
wherein: t is e * Corresponding to the excitation current reference signal, omega, for the virtual control quantity Inner part Is the mechanical angular velocity, x, of the motor side 1 、x 2 For a defined sliding-mode state variable,is a reference value of the angular velocity of the motor side,the mechanical angular acceleration at the motor side, the moment of inertia of the load at the motor side, D, k, and delta 0 For controlling the constant of the parameter, sign (-) is a sign function, λ >0 is a design parameter, q, p are positive odd numbers, and q is<p<2q。
6. The CMG frame system harmonic reducer disturbance rejection system of claim 4, wherein: the control law of the inner loop current controller is as follows:
wherein u is d 、u q For d-and q-axis stator voltage components, i d 、i q Are d-axis and q-axis stator current components,calculating the error for the current i d * 、i q * D-axis and q-axis stator current reference values; r is stator resistance, L is motor inductance, L d 、L q Is a direct-axis and quadrature-axis synchronous inductor of the motor, omega e For electrical angular velocity, psi, of the motor rm For rotor flux linkage, gamma 1 >0,δ 1 >0,γ 2 >0,δ 2 >0, are all constants.
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